high performance needs great design. Datasheet: AS8510 Data Acquisition Device for Battery Sensors Please be patient while we update our brand image as austriamicrosystems and TAOS are now ams. www.ams.com AS8510 D a t a A cq u is i t io n D ev ic e f o r B a t t e r y S e n s o r s 1 General Description Option for multiplexing either one differential input, or two single ended inputs or the internal temperature sensor on one channel The AS8510 is a virtually offset free, low noise, two channel measurement device. It is tailored to accurately measure battery current from mA range up to kA range in conjunction with a 100 µΩ shunt resistor in series with the battery rail. Through the second measurement channel it enables capture of, either battery voltage synchronous with the current measurement, or, measure the analog output of an internal or external temperature sensor. Both channels are matched and can either measure small signals up to ±160 mV versus ground, through programmable gain amplifier or larger signals in the 0 to 1V range without the amplifier. Programmable current source for external temperature sensor connectable to any of the inputs High precision and high stability 1.2V reference voltage source Digital signal processing with filter options for both channels Four operating modes providing - Continuous data acquisition (or) - Periodic single-shot acquisition, (or) - Continuous acquisition on threshold crossing of programmed current levels (or) - A combination of the above On chip high-precision 4MHz RC oscillator or option for external clock After analog to digital conversion and digital filtering, the resulting 16-bit digital words are accessible through 4-wire standard serial interface.The device includes a number of additional features explained in the next section. 2 Key Features -40ºC to +125ºC ambient operation AEC - Q100 automotive qualified 3.3V supply voltage Two High resolution 16 bit Internal chip ID for full traceability Σ−Δ A/D converters SSOP-20 pin package Programmable sampling to enable data throughputs from less than 1Hz to 8kHz 3 Applications Zero Offset for both channels Independent control of data rate on both channels The AS8510 is ideal for shunt based batteries sensor. For high-side current sensing, the input signal may be conditioned using ams device AS8525 before applying to this device. Precision, low noise, programmable gain amplifiers for both channels with gains 5, 25, 40, 100 to support wide dynamic ranges. Figure 1. AS8510 Block Diagram Internal Temperature Sensor ETS Bandgap Reference Oscillators Prog-Cur Source ETR VBAT_IN DVDD REF AVDD MUX and Chopper 16-bit Sigma-Delta ADC PGA MEN VBAT_GND AS8510 RSHH FIR / MA CHOP_CLK INT CLK Chopper PGA 16-bit Sigma-Delta ADC RSHL Analog Common Mode AVSS www.ams.com/AS8510 VCM Serial Interface SCLK CS Revision 3.5 SDI SDO DVSS 1 - 46 AS8510 Datasheet - C o n t e n t s Contents 1 General Description .................................................................................................................................................................. 1 2 Key Features............................................................................................................................................................................. 1 3 Applications............................................................................................................................................................................... 1 4 Pin Assignments ....................................................................................................................................................................... 4 4.1 Pin Descriptions.................................................................................................................................................................................... 4 5 Absolute Maximum Ratings ...................................................................................................................................................... 6 6 Electrical Characteristics........................................................................................................................................................... 7 6.1 Operating Conditions............................................................................................................................................................................ 7 6.2 DC/AC Characteristics for Digital Inputs and Outputs .......................................................................................................................... 7 6.3 Detailed System and Block Specifications ........................................................................................................................................... 9 6.3.1 Electrical System Specifications .................................................................................................................................................. 9 6.4 Current Measurement Ranges (across 100µΩ shunt resistor)............................................................................................................ 9 6.4.1 Differential Input Amplifier for Current Channel ......................................................................................................................... 6.4.2 Differential Input Amplifier for Voltage Channel......................................................................................................................... 6.4.3 Sigma Delta Analog to Digital Converter ................................................................................................................................... 6.4.4 Bandgap Reference Voltage...................................................................................................................................................... 6.4.5 Internal (Programmable) Current Source for External Temperature Measurement .................................................................. 6.4.6 CMREF Circuit (VCM) ............................................................................................................................................................... 6.4.7 Internal AVDD Power-on Reset ................................................................................................................................................. 6.4.8 Internal DVDD Power-on Reset................................................................................................................................................. 6.4.9 Low Speed Oscillator................................................................................................................................................................. 6.4.10 High Speed Oscillator .............................................................................................................................................................. 6.4.11 External Clock.......................................................................................................................................................................... 6.4.12 Internal Temperature Sensor................................................................................................................................................... 10 11 12 12 13 13 13 14 14 14 14 15 6.5 System Specifications ........................................................................................................................................................................ 7 Detailed Description................................................................................................................................................................ 15 16 7.1 Current Measurement Channel .......................................................................................................................................................... 16 7.2 Voltage/Temperature Measurement Channel ..................................................................................................................................... 16 7.3 Digital Implementation of Measurement Path..................................................................................................................................... 17 7.4 Modes of Operation ............................................................................................................................................................................ 17 7.4.1 7.4.2 7.4.3 7.4.4 Normal Mode 1 (NOM1) ............................................................................................................................................................ Normal Mode 2 (NOM2) ............................................................................................................................................................ Standby Mode1 (SBM1) ............................................................................................................................................................ Standby Mode2 (SBM2) ............................................................................................................................................................ 19 19 20 21 7.5 Reference-Voltage.............................................................................................................................................................................. 21 7.6 Oscillators........................................................................................................................................................................................... 21 7.7 Power-On Reset ................................................................................................................................................................................. 21 7.8 4-Wire Serial Port Interface ................................................................................................................................................................ 22 7.8.1 7.8.2 7.8.3 7.8.4 7.8.5 SPI Frame.................................................................................................................................................................................. Write Command......................................................................................................................................................................... Read Command......................................................................................................................................................................... Timing ........................................................................................................................................................................................ SPI Interface Timing .................................................................................................................................................................. www.ams.com/AS8510 Revision 3.5 22 23 24 25 26 2 - 46 AS8510 Datasheet - C o n t e n t s 7.9 Control Register.................................................................................................................................................................................. 7.9.1 7.9.2 7.9.3 7.9.4 7.9.5 7.9.6 Standby Mode - Power Consumption ........................................................................................................................................ Initialization Sequence at Power ON ......................................................................................................................................... Soft-reset of Device Using Bit D[7] of Reset Register 0x09....................................................................................................... Soft-reset of the Measurement Path Using Bit D[7] of Reset Register 0x09 ............................................................................. Reconfiguring Gain Setting of PGA .......................................................................................................................................... Configuring the Device During Normal Mode ............................................................................................................................ 7.10 Low Side Current Measurement Application .................................................................................................................................... 8 Package Drawings and Markings ........................................................................................................................................... www.ams.com/AS8510 Revision 3.5 41 42 8.1 Recommended PCB Footprint............................................................................................................................................................ 9 Ordering Information............................................................................................................................................................... 27 37 38 39 39 40 40 43 45 3 - 46 AS8510 Datasheet - P i n A s s i g n m e n t s 4 Pin Assignments Figure 2. Pin Assignments (Top View) RSHH 1 20 INT RSHL 2 19 CLK REF 3 18 SDI VCM 4 17 MEN AVDD 5 16 CHOP_CLK AVSS 6 15 DVDD ETR 7 14 DVSS ETS 8 13 SDO VBAT_IN 9 12 SCLK 10 11 CS VBAT_GND AS8510 4.1 Pin Descriptions Table 1. Pin Descriptions Pin Number Pin Name Pin Type Description 1 RSHH 2 RSHL 3 REF 4 VCM 5 AVDD 6 AVSS 7 ETR 8 ETS 9 VBAT_IN 10 VBAT_GND 11 CS 12 SCLK Digital input Clock signal (SPI Interface) 13 SDO Digital output Serial Data Input (SPI Interface) Analog input Analog output www.ams.com/AS8510 Supply pad Positive Differential input for current channel Negative differential input for current channel Internal reference voltage to sigma-delta ADC; connect 100nF to AVSS from this pin. Common Mode voltage to the internal measurement path; connect 100nF to AVSS from this pin. +3.3V Analog Power-supply 0V Power-supply analog Voltage channel single ended input Analog input Battery voltage (high) input Battery voltage (low) input Digital input with pull-up Chip select with an internal pull-up resistor (SPI Interface) Revision 3.5 4 - 46 AS8510 Datasheet - P i n A s s i g n m e n t s Table 1. Pin Descriptions Pin Number Pin Name 14 DVSS 15 DVDD 16 Pin Type Description Supply pad CHOP_CLK Digital output 17 MEN 18 SDI 19 CLK 20 INT www.ams.com/AS8510 Digital input Digital I/O Digital output 0V Digital Ground +3.3V Digital Supply Chop Clock used in High side measurements to synchronize external chopper. (As an example, when AS8525 is used to condition the input signal to the input range of AS8510, the chop clock is used by AS8525.) Digital output issued during the Standby Mode (SBM) to signal the short duration of data sampling. This signal is useful in the case of a High Side Measurement application. (For example: This signal is used by AS8525 device to wake-up and enable the measurement path.) Data signal (SPI Interface) By default this pin is the internal clock output which can be used by a Microcontroller. The internal clock may also be disabled as an output by programming Register 08. To use an external Clock, Register 08 has to be programmed. Active High Interrupt to indicate data is ready Revision 3.5 5 - 46 AS8510 Datasheet - A b s o l u t e M a x i m u m R a t i n g s 5 Absolute Maximum Ratings Stresses beyond those listed in Table 2 may cause permanent damage to the device. These are stress ratings only. Functional operation of the device at these or any other conditions beyond those indicated in Electrical Characteristics on page 7 is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Table 2. Absolute Maximum Ratings Parameter Min Max Units Notes DC supply voltage (AVDD and DVDD) -0.3 5 V Input voltage (VIN) -0.3 AVDD + 0.3 DVDD + 0.3 V Input current (latchup immunity) (ISCR) -100 100 mA AEC - Q100 - 004 ±2 kV AEC - Q100 - 002 50 mW SSOP20 in still air, soldered on JEDEC standard board @ 125º ambient, static operation with no time limit 125 ºC Junction temperature (TJ) 130 ºC Thermal resistance (RthJC) 80 K/W JEDEC standard test board, 0 air velocity 260 ºC Norm: IPC/JEDEC J-STD-020 The reflow peak soldering temperature (body temperature) is specified according IPC/ JEDEC J-STD-020 “Moisture/Reflow Sensitivity Classification for Nonhermetic Solid State Surface Mount Devices”. The lead finish for Pb-free leaded packages is matte tin (100% Sn). 85 % Electrical Parameters Electrostatic Discharge Electrostatic discharge (ESD) all pins Continuous Power Dissipation Total power dissipation (all supplies and outputs) (Pt) Temperature Ranges and Storage Conditions Storage temperature (TSTRG) -50 Package body temperature (TBODY) Humidity non-condensing www.ams.com/AS8510 5 Revision 3.5 6 - 46 AS8510 Datasheet - E l e c t r i c a l C h a r a c t e r i s t i c s 6 Electrical Characteristics 6.1 Operating Conditions Table 3. Operating Conditions Symbol Parameter AVDD Conditions Min Max Units Positive analog supply voltage 3.0 3.6 V AVSS 0V Ground 0 0 V A-D Difference in analog and digital supplies 0.1 V DVDD Positive digital supply 2.97 3.63 V DVSS 0V Digital Ground 0 0 V TAMB Ambient temperature -40 125 ºC ISUPP Supply current 5.5 mA fCLK System clock frequency 4.096 MHz 1 1. Nominal clock frequency from external or internal oscillator. 6.2 DC/AC Characteristics for Digital Inputs and Outputs All pull-up and pull-down have been implemented with active devices. SDO has been measured with 10pF load. Table 4. INT Symbol Parameter Conditions Min Typ Max Units ILEAK Tri-state leakage current -1 +1 µA VOH High level output voltage 2.5 VOL Low level output voltage 0.4 V IO Output Current 4 mA Max Units V Table 5. CS Input Symbol Parameter VIH High level input voltage VIL Low level input voltage ILEAK Input leakage current Ipu Pull up current Symbol Parameter VIH High level input voltage VIL Low level input voltage ILEAK Input leakage current Conditions Min Typ 2.0 V 0.8 V -1 +1 µA CS pulled to DVDD = 3.3V -150 -15 µA Conditions Min Max Units Table 6. SDI www.ams.com/AS8510 Typ 2.0 -1 Revision 3.5 V 0.8 V +1 µA 7 - 46 AS8510 Datasheet - E l e c t r i c a l C h a r a c t e r i s t i c s Table 7. SDO Output Symbol Parameter Conditions Min VOH High level output voltage Isource = 8mA 2.5 VOL Low level output voltage Isink = 8mA Io Output Current Typ Max Units V 0.4 V 8 mA Max Units Table 8. CHOP_CLK Output Symbol Parameter Conditions Min Typ VOH High level output voltage VOL Low level output voltage 0.4 V Io Output Current 4 mA Max Units 2.5 V Table 9. CLK I/O with Input Schmitt Trigger and Output Buffer Symbol Parameter Conditions Min VIH High level input voltage DVDD = 3.3V 2.4 VIL Low level input voltage DVDD = 3.3V ILEAK Input leakage current IPD Pull down current Io Output Current VOH High level output voltage VOL Low level output voltage CLK pulled to DVSS Typ V 1.0 V -1 +1 µA 10 100 µA 4 mA 2.5 V 0.4 V Max Units Table 10. SCLK with Input Schmitt Trigger Symbol Parameter Conditions Min VIH High level input voltage DVDD = 3.3V 2.4 VIL Low level input voltage DVDD = 3.3V ILEAK Input leakage current Typ V -1 1.0 V +1 µA Max Units Table 11. MEN Output Symbol Parameter VOH High level output voltage VOL Low level output voltage 0.4 V IO Output Current 2 mA www.ams.com/AS8510 Conditions Min Typ 2.5 Revision 3.5 V 8 - 46 AS8510 Datasheet - E l e c t r i c a l C h a r a c t e r i s t i c s 6.3 Detailed System and Block Specifications 6.3.1 Electrical System Specifications Table 12. Electrical System Specifications Symbol Parameter IDDNOM IDDSBM Min Typ Max Units Current consumption normal mode 3 5.5 mA Current consumption standby mode 40 µA Notes Average of NORMAL Mode Power consumption over a period of 10sec when the device is in STANDBY Mode 6.4 Current Measurement Ranges (across 100µΩ shunt resistor) Table 13. Current Measurement Ranges Symbol Parameter Imax [A] Vsh [mV] PGA Gain Nominal Data Rate (fOUT) VINADC [mV] PSR [dB] I10 Input current range of 10A in NOM ±10 ±1 100 @ 1 kHz ±100 60 I200 Input current range of 200A in NOM ±200 ±20 40 @ 1 kHz ±800 60 I400 Input current range of 400A in NOM ±400 ±40 25 @ 1 kHz ±1000 60 I1500 Input current range of 1500A in NOM ±1500 ±150 5 @ 1 kHz ±750 60 I1 Input current range of 1A in SBM ±1 ±0.1 100 @ 1 Hz ±10 60 I10 Input current range of 10A in SBM ±10 ±1 100 @ 1 Hz ±100 60 I200 Input current range of 200A in SBM ±200 ±20 40 @ 1 Hz ±800 60 3 3 3 1 2 1. VINADC = Vsh * Gain, gain deviations to be considered according to Table 15 and Table 16. 2. AVDD, DVDD of 3.3V with ±5% variation. 3. For low power current monitoring, single shot measurement is performed with internal oscillator. Note: The Data Rate at the output can be calculated according to the formula: fsout=2*fchop /R2 (R2 is down sampling ratio taking values 1, 2, 4 up to 32768 as powers of 2) Table 14. Valid Combinations of the Chopper Clock, Oversampling Clock and Decimation Ratios Over Sampling Frequency Chopper Frequency Decimation Ratio 1.024MHz 2kHz 64 2.048MHz 2kHz 64 2.048MHz 2kHz 128 2.048MHz 4kHz 64 www.ams.com/AS8510 Revision 3.5 9 - 46 AS8510 Datasheet - E l e c t r i c a l C h a r a c t e r i s t i c s 6.4.1 Differential Input Amplifier for Current Channel Table 15. Differential Input Amplifier for Current Channel Symbol Parameter Conditions Min VIN_AMP Input voltage range RSHH and RSHL -160 RSHH and RSHL@ +160mV input voltage at 125ºC with PGA -50 IIN_AMP ICM Input current 1, 11 Absolute input voltage range Typ 2 Gain1 3, 4, 9 I10 100 G = G2 Gain2 3, 4, 9 I200 40 G = G3 Gain3 3, 4, 9 I400 25 G = G4 Gain4 3, 4, 9 I1500 5 Gain deviation fP_AMP Pole frequency εT1 VOSDRIFT i = 1, 2, 3, 4 4, 5 Vos Input referred offset 7, 10 Vos_ch VNdin THD 6 7, 10 mV 50 nA mV 1.1 * Gi kHz ±0.3 350 After trim, for temperature range -20 to +65ºC 4, 8 Total harmonic distortion 0.9 * Gi -20ºC to +65ºC Gain 5, 25, referenced to room temperature Chopping enabled Noise density +160 15 Gain drift with temperature Offset drift with temperature Units -160 +300 2 G = G1 e Max For 150 Hz input signal % µV 350 µV 0 LSB 25 nV/√Hz 70 dB Notes: 1. Leakage test accuracy is limited by tester resource accuracy and tester hardware. 2. For gain 100 PGA input common mode is 0V and the minimum supply is 3.15V. 3. The measurement ranges are referred only by the gain of input amplifier, while other parameters such as bandwidth etc. are programmed independently. 4. This parameter is not measured directly in production. It is measured indirectly via gain measurements of the whole path. It is guaranteed by design. 5. Pole frequency of input amplifier changes with GAIN. The number is valid for the gain at G1, while the bandwidth will be higher for other ranges. This parameter is not measured in production. 6. Based on device evaluation. Not tested. 7. These offsets are cancelled if chopping enabled (default). 8. Noise density calculated by taking system bandwidth as 150Hz. 9. Refer to Measurement Ranges shown in Table 13. 10. No impact on the measurement path. If the chopping is enabled, both the offset and offset drift will be eliminated. 11. For negative input voltages up to -160mV below ground, Input leakage is typically -20nA @ 65ºC due to forward conductance of protection diode. www.ams.com/AS8510 Revision 3.5 10 - 46 AS8510 Datasheet - E l e c t r i c a l C h a r a c t e r i s t i c s 6.4.2 Differential Input Amplifier for Voltage Channel Table 16. Differential Input Amplifier for Voltage Channel Symbol Parameter Conditions VIN_AMP Input voltage range IIN_AMP Input current ICM 1, 10 Min Typ -160 VBAT_IN, ETR, ETS @ +160mV input voltage at 125ºC with PGA 2, 10 -50 G = G1 Gain1 4, 5 100 G = G2 Gain2 4, 5 40 G = G3 Gain3 4, 5 25 G = G4 Gain4 4, 5 5 e Gain deviation fP_AMP Pole frequency VNDIN Noise density i = 1, 2, 3, 4 5, 6 5, 7 Total harmonic distortion εT1 Gain drift with temperature Input referred offset Vos_ch VOSDRIFT +160 mV 50 nA 0.9 * Gi mV 1.1 * Gi 15 THD VOS Units -160 +300 3 Absolute input voltage range 2 Max For 150Hz input signal 8 9 Offset drift with temperature kHz 25 nV/√Hz 70 dB -20ºC to +65ºC Gain 5, 25, referenced to room temperature ±0.3 % After trim at +65ºC 350 µV Chopping enabled 9 0 LSB 350 µV Notes: 1. Input for the voltage channel can be as high as 1220mV, in this high input case PGA will be bypassed. 2. Leakage test accuracy is limited by tester resource accuracy and tester hardware, especially at low temperatures due to condensing moisture. 3. For gain 100 PGA input common mode is 0V and the minimum supply is 3.15V. 4. The measurement ranges are referred only by the gain of input amplifier, while other parameters such as bandwidth etc. are programmed independently. 5. This parameter is not measured directly in production. It is measured indirectly via gain measurements of the whole path. It is guaranteed by design. 6. Pole frequency of input amplifier changes with changing the GAIN. The number is valid for the gain at G1, while the bandwidth will be higher for other ranges. This parameter is not measured in production. 7. Noise density calculated by taking system bandwidth as 150Hz. 8. Based on device evaluation. Not tested. 9. No impact on the measurement path. If the chopping is enabled, both the offset and offset drift will be eliminated. 10. For negative input voltages up to -160mV below ground, Input leakage is typically -20nA @ 65ºC due to forward conductance of protection diode. www.ams.com/AS8510 Revision 3.5 11 - 46 AS8510 Datasheet - E l e c t r i c a l C h a r a c t e r i s t i c s 6.4.3 Sigma Delta Analog to Digital Converter Table 17. Sigma Delta Analog to Digital Converter Symbol Parameter Conditions Min 6 VREF Reference voltage VINADC Input range R1 Oversampling ratio/Decimation Ratio fovs Oversampling frequency RES Number of bits BW Bandwidth S/N Signal to noise ratio Typ Max 1.225 1 At Vref = 1.22V 2 0 64 V ±1.22 128 4 1 5 V 128 1024/ 2048 3 Units kHz 16 bits 500 Hz 90 dB Notes: Production test at ±800mV. Maximum VIN can be 1.22V with VREF=1.225V. Programmable. It is defined with respect to the first decimator in the ΣΔ ADC. Programmable: Internal clock is 1024/2048 kHz; external clock max is 8192 kHz. Dependent on fovs, R1 and R2. The bandwidth is calculated according to the formula: BW=fovs/(2*R1*R2); the sampling frequency at the output of the A/D converter is 2*BW. 5. Defined at maximum input signal, BW=500 Hz (1Hz to 500 Hz), fovs=1024 kHz, R1=64, fchop=2 kHz and R2=2. 6. Reference voltage might be forced from external. 1. 2. 3. 4. 6.4.4 Bandgap Reference Voltage Table 18. Bandgap Reference Voltage Symbol Parameter Conditions 1, 2 VREFTRIM Reference Voltage after trim VREFACC Reference Voltage Initial Accuracy VREFDRIFT Trim at 65ºC 1, 2 Reference Voltage Temperature drift PSRRREF PSR @ dc SUTAVDD Start Up Time with supply ramp 3 SUTPD Start Up Time from power down 3 RNDVREF Output resistance of band gap VNDVREF Bandgap reference thermal noise density CLVREF ESRVREF Min Typ Max 1.225 Units V At 65ºC ±3.5 mV Temperature range -20 to 65 ºC ±0.4 % Temperature range -40 to 125 ºC +0.4/ -0.6 % 80 dB 5 ms 500 3 1 ms 1000 Ω 300 nV/√Hz 100 Output Capacitor (Ceramic) 0.02 nF 1 Ω Notes: 1. Accuracy at 65ºC. 2. No DC current is allowed from this pin. 3. This is a design parameter and not production tested. www.ams.com/AS8510 Revision 3.5 12 - 46 AS8510 Datasheet - E l e c t r i c a l C h a r a c t e r i s t i c s 6.4.5 Internal (Programmable) Current Source for External Temperature Measurement Table 19. External Temperature Measurement Symbol Parameter ICURON 5-bit current source enabled ICUROFF 5-bit current source disabled TK_CS Temperature coefficient of current source VMAXETR Voltage on pin ETR VMAXETRMOD Max voltage on pin ETR when PGA is 4 bypassed VMAXETS Voltage on pin ETS for resistor sensor VMAXETSMOD Max. Voltage on pin ETS when PGA is 5 bypassed 1 Conditions Min Typ Max Units 5-bit programmable current source 0 270 320 µA Limited by leakage 2 10 nA 1000 ppm / ºK 3 3 1000/G mV 1.22 V 1000/G V 1.22 V Notes: 1. Current value can be programmed in steps of 8μA from 0 to 256μA with a process error of 30%. 2. Temperature coefficient is not important since external temperature measurement is a 2 step measurement. The value specified is guaranteed by design and will not be tested in production. 3. Maximum voltage on pin ETR (reference) can be calculated by given formula, where G is the gain of PGA (G=100). 4. Maximum voltage on pin ETR, if PGA is bypassed. 5. Maximum voltage on pin ETS, if PGA is bypassed. 6.4.6 CMREF Circuit (VCM) Table 20. CMREF Circuit 6.4.7 Symbol Parameter Min Typ Max Units VVCM Output voltage 1.6 1.7 1.8 V CL Load capacitance 100 nF Internal AVDD Power-on Reset Table 21. Internal AVDD Power-on Reset Symbol Parameter Power On Reset Threshold VPORHIA tPORA POR time - The duration from Power ON till the time, internal Power On Reset signal 1 goes HIGH IPORA Current consumption in POR block Min Typ Max Units 2.2 2.4 2.6 V 1 2 µs 1.5 µA 1. POR pulse is always longer than tPORA whatever the slope of the supply. 2. IPORA can not be switched off. www.ams.com/AS8510 Revision 3.5 13 - 46 AS8510 Datasheet - E l e c t r i c a l C h a r a c t e r i s t i c s 6.4.8 Internal DVDD Power-on Reset Table 22. Internal DVDD Power-on Reset Symbol Parameter Power On Reset Threshold VPORHID 1 Min Typ Max Units 2.2 2.4 2.7 V 0.25 0.4 V VHYST Hysteresis 0.2 tPORD POR time - The duration from Power ON till the time, internal Power On Reset signal goes 2 HIGH 1 IPORD Current 3 µs 1.5 µA 1. VPORLO = VPORHI - VHYST where VPORLO is the lower threshold of POR. 2. VPORLO = VPORHI - VHYST where VPORLO is the lower threshold of POR. 3. IPORD can not be switched off. 6.4.9 Low Speed Oscillator Table 23. Low Speed Oscillator Symbol Parameter Min Typ Max Units fLS Frequency 262.144 kHz fLS_ACC Accuracy ±7 % ILS Supply current 5 µA 6.4.10 High Speed Oscillator Table 24. High Speed Oscillator Symbol Parameter fHS Frequency fHSACC Accuracy Min 1, 2 Supply current IHS Typ Max Units 4.096 MHz ±4 % 300 µA Notes: 1. Accuracy after trimming. 2. Accuracy for limited temperature range of -20 to 65 ºC. 6.4.11 External Clock Table 25. External Clock Symbol Parameter fCLKEXT Clock frequency DIVCLKEXT Clock division factor DCCLKEXT Duty Cycle of external clock www.ams.com/AS8510 Conditions Min Typ Max 2048/ 4096/ 8192 to be programmed in Register 08 CLK_REG through the serial bus SPI. kHz 2/4/8 40 Revision 3.5 Units 60 % 14 - 46 AS8510 Datasheet - E l e c t r i c a l C h a r a c t e r i s t i c s 6.4.12 Internal Temperature Sensor Table 26. Internal Temperature Sensor Symbol Parameter Conditions TINTRNG Temperature sensor range ΔTIN Temperature measurement accuracy TINTSLP Temperature sensor slope TINT65G5 Temperature sensor output at gain 5 Min Typ -40 Guaranteed by design; at PGA gain 5 which is the recommended Gain for internal temperature measurement. 40660 Max Units 125 ºC 3 ºC 27 Digits/C 41807 43012 Digits 6.5 System Specifications Table 27. System Specifications Symbol Parameter Min Typ 1 Max Units -90 dB IS Channel to channel isolation At Difference in channel to channel attenuation 1, 2 @600Hz 3 dB Ph Difference in phase shift between the two 1, 2 channels @600Hz 5 Deg System Measurement Error Budget for Voltage and Current Channel. Temperature Range: -20ºC to +65ºC; Output data rate is 1kHz, VCC = 3.3V, chopping enabled. Table 28. System Measurement Error Budget for Gains 5 and 25 Symbol Err Parameter System measurement error Conditions 3, 4 Measurement error due to PGA gain drift From device evaluation Measurement error due to VREF drift6 Measurement error due to non-linearity of PG Tested by distortion measurements Min Typ Max Units ±0.5 ±0.8 % ±0.3 % ±0.4 % ±0.025 % Notes: 1. 2. 3. 4. These specifications are defined by taking one channel as reference and measured on the other channel. Guaranteed by design. System measurement error due to noise, individual block parameter drifts and non linearity. Based on evaluation, not tested. System error due to offset is neglected because of chopper architecture. www.ams.com/AS8510 Revision 3.5 15 - 46 AS8510 Datasheet - D e t a i l e d D e s c r i p t i o n 7 Detailed Description The AS8510 consists of two independent high resolution 16-bit SD analog to digital conversion channels. The measurement path of these two channels integrates a programmable gain amplifier, chopper and de-chopper, sigma-delta modulator, decimator and a digital filter for simultaneous measurement of Current and Voltage/Temperature. The two measurement channels, namely the Current and Voltage/Temperature measurement channels have identical data path. The input signal is amplified in the Programmable Gain Amplifier (PGA) with any of the selected gains of 1, 5, 25, 40 and 100 facilitating measurement of a wide range of Current, voltage and temperature levels. Gain Settings for different input ranges and any associated restrictions are explained in the Table 13. Offset in the measurement path is minimized with the use of a chopper and a de-chopper at appropriate stages in the data path. By default the chopper/de-chopper is ON in the measurement path. It may be disabled by programming the appropriate register. The amplified input signal is converted into a single-bit pulse-density modulated stream by the Σ-Δ Modulator. A decimator acting as a low-pass filter filters out the quantization noise and generates 16-bit data corresponding to the input signal. The decimation ratios of 64, 128 may be selected in the first filter stage. For reducing data rate further, the second stage decimation can be used. An optional FIR Filter is provided to offer matched low pass filter response typically required in lead acid battery sensor systems. 7.1 Current Measurement Channel The voltage across a Shunt Resistor, connected in series with the Battery negative terminal, forms the input signal to the Current Measurement channel. RSHH and RSHL are the Current measurement input pins. Offset in the input signal is nullified with the use of a chopper and a dechopper at appropriate stages in the data path. The programmable gain amplifier in the data path with programmable settings of 1, 5, 25, 40 and 100 enables measurement of current ranges from ±1A to ±1500A. The sampled input signal is converted into a single-bit pulse-density modulated stream by the Σ-Δ Modulator. A decimator acting as a low-pass filter filters out the quantization noise and generates 16-bit data equivalent to the input current signal. The programmable input sampling rate and the decimation ratio determine the output data rates. The data path can be programmed to provide 1Hz to 2 kHz rates in the various modes available. An optional FIR filter is provided to offer matched low pass filter response typically required in lead acid battery sensor systems. After enabling the current measurement channel, the delay for the availability of the first sample is two conversion cycles. 7.2 Voltage/Temperature Measurement Channel The other two parameters of the Battery for measurement are Voltage and its Temperature. The second channel accepts signals from four independent sources through a Multiplexer as listed below: An attenuated battery voltage obtained through appropriate external resistor divider, (or) A signal from the external temperature sensor, (or) A signal from external reference, (or) A signal from the internal temperature sensor. Apart from this difference in the multiplexing of four input signals, the rest of the data path is identical to the Current measurement channel. RSHH and RSHL are the Current measurement input pins The Battery Voltage which can go up to 18V is attenuated through a Resistor Divider externally and is applied to the Voltage Channel. For Automotive Battery measurement, the Gain of the PGA should be restricted to 5 and 25. The latency for the first result from the voltage measurement channel is two conversion cycles. A second option on this measurement channel is to measure Temperature. Internally generated constant current is pumped through the Temperature Sensor with positive temperature coefficient, and, a high- precision resistor. The voltages across the sensor and the resistor form the inputs to the measurement channel one at a time. The difference between the two voltages which is independent of the magnitude of the current is used to determine the temperature accurately. The Voltage across the sensor is applied between the ETS and VSS pins and, the voltage across the high-precision resistor is applied between ETR and VSS. External Temperature measurement involves the acquisition of two signals one after the other using the same constant current source. The latency for the first result from the temperature measurement channel is two conversion cycles. A third option on the measurement channel is to measure the internal temperature. Hence, one of the three options for measurement of Battery Voltage, External Temperature and, internal temperature may be carried out by selection of appropriate inputs through the internal multiplexer selection. www.ams.com/AS8510 Revision 3.5 16 - 46 AS8510 Datasheet - D e t a i l e d D e s c r i p t i o n 7.3 Digital Implementation of Measurement Path Figure 3. Block Diagram of Digital Implementation R2 R1 CIC1 64 / 128 Dechopper fmod MOD_CLK fchop * 2 / R2 fchop * 2 fmod / R1 MOD_IN fchop FIR_MA_SEL CIC2 R1 fchop * 2 / R2 FIR/MA DATAOUT R1 = First decimation ratio (64 or 128) R2 = Second decimation ratio (1 to 32768) CHP_CLK CLK DIVISION BLOCK MOD_CLK Figure 3 shows the digital implementation of the decimator and filter to process the 1-bit output of the Modulator. This block receives a 1-bit pulse density modulated output (MOD_IN) from the second order sigma delta modulator along with the oversampling frequency clock (MOD_CLK). The MOD_CLK directly goes to a clock division block, which generates chopper clock (CHOP_CLK). The CHOP_CLK can be one of 2kHz or 4kHz selected by Register CLK_REG in Table 33. The MOD_CLK can be either 1MHz or 2MHz. The Decimation is a two phase process. In the first phase, the R1 down sampling rate can be obtained by selecting either 64 or 128 in Registers DECREG_R1_I, DECREG_R1_V in Table 33. The 16-bit CIC1 output is dechopped with respect to CHOP_CLK. The output of Dechopper is passed through the CIC2 filter with a decimation ratio of 1to 32768 in steps of power of 2. This output is then processed through a FIR or Moving Average (MA) filter. FIR Filter is provided to offer matched low pass filter response typically required in lead acid battery sensor systems. MA filter is used to provide averaged output and the number of samples for averaging can be any integer value from 1 to 15. 7.4 Modes of Operation The device operates in four different modes, namely, Normal Mode 1 (NOM1), Normal Mode 2 (NOM2), Standby Mode 1 (SBY1), and, Standby Mode 2 (SBY2). The Normal Modes are full-power modes with the exception that in Normal Mode 2, sampling is normally at a programmed lower frequency and is increased to a higher rate only when a measured input signal level crosses the programmed threshold in the current measurement channel. The Standby Modes are lower power modes. Sampling is normally at a very low frequency interval. In Standby Mode 2, data sampling can be carried out only when the internal comparator detects the input current to be greater than the programmed threshold and it generates interrupt on the INT pin. The device enters into the “Stop” state on Power On. This is a state where in the data path is inactive and can be entered into from any of the four Modes. The State transition Diagram involving the state of Stop and the four Modes is illustrated in the Figure 4. www.ams.com/AS8510 Revision 3.5 17 - 46 AS8510 Datasheet - D e t a i l e d D e s c r i p t i o n !por_dvdd Figure 4. State Transition Diagram por_avdd !por_avdd RESET Wait for otp_load Completes in 32 cycles of lp_clk otp_load OTP_INT STOP sto p 1.5msec & NORM A_STB SBM p NO RM sto ut eo tim 1_ TT Wait for x number of conversions NORM NORM or stop 1.5msec & SBM Analog Stablization period Wait for 1.5msec rt stop s ta SBM_ON SBM SBM_OFF Wait for TT1 timeout Note: 1. Device soft reset can be written in any of the following states STOP, A_STB, SBM_ON, SBM_OFF by writing “0” into D[7] of the RESET _REG (Address 0X09). 2. Measurement path of soft reset should be written in any the states, STOP, SBM_OFF by writing “0” into D[6] of the RESET _REG (Address 0X09). 3. When soft reset is used for the measurement path or for the device, external clock needs to be disabled if the system clock is external clock in the application. www.ams.com/AS8510 Revision 3.5 18 - 46 AS8510 Datasheet - D e t a i l e d D e s c r i p t i o n 7.4.1 Normal Mode 1 (NOM1) On Power-on-reset of the device, AS8510 goes into STOP State. Transition to Normal mode1 (NOM1) occurs when the “START BIT” D0 of Mode Control Register MOD_CTL_REG in Table 33 is set to “1” through the serial port SPI. Data Rate of voltage and current channels can be independently programmed and both the channels generate interrupts for every output available from ADC. The interrupt signal is generated on the INT pin. The width of the interrupt pulse is eight cycles of lp_clk. The data is stable up to the next interrupt. If the data rate is different for the two channels, the interrupt rate would follow the higher rate among the two channels. Data update can be known by reading the status register. The functionality is explained in the waveform shown in Figure 5. When the device is configured to NORMAL Mode1 from any mode the configuration should be through the STOP state only. Figure 5. Normal Mode 1 I IDATA Sampling with f1 t V,T V,TDATA Sampling with f2 t STOP START Current Channel DATA Register Voltage Channel DATA Register INT at f1 rate from current channel 7.4.2 Interrupt from the current channel is at f1 rate which is integer multiple of f2 rate from voltage channel TINT Normal Mode 2 (NOM2) NOM2 differs from NOM1 in such a way that it allows for a relaxed data rate at a period of TMC by programming the corresponding register as long as the amplitude of current is less than a programmed threshold ITHC. However, when, the measured input signal exceeds the programmed threshold, the data rate is changed to the rate of NOM1 mode. Transition to NOM2 occurs when the “START BIT” D0 of Mode Control register MOD_CTL_REG in Table 33 is set to 1 and mode control bits to 01 through SPI. In this mode the data rate should be programmed with the time of TMC. An interrupt signal is generated on INT at the rate of TMC secs with a pulse width of eight cycles of lp_clk. The data is stable up to the next interrupt. The data sample is compared against the programmed threshold and when it is exceeded, the data sampling rate is changed to provide data at the data rate of NOM1 mode. However, as soon as the data sample amplitude falls below the programmed threshold, the sampling rate is restored to provide data at the rate of TMC. The functionality is illustrated in the waveform Figure 6. www.ams.com/AS8510 Revision 3.5 19 - 46 AS8510 Datasheet - D e t a i l e d D e s c r i p t i o n Figure 6. Normal Mode 2 I I < I THS V,I,T I DD V,I,T V,I,T TMC V,I,T V,I,T TMC ITHS t Sampling with f I > I THS INT T INT 7.4.3 Standby Mode1 (SBM1) The low-power Standby Mode can be entered only through the STOP state. Transition to SBM1 mode occurs when the “START BIT” D0 of Mode Control register MOD_CTL_REG in Table 33 is set to “1” and Mode Control Bits to “10” through SPI. In this mode the date rate is programmable with the time of Ta. An interrupt signal is generated on INT at the rate of Ta secs., and with a pulse width of eight cycles of lp_clk. The data is stable up to the next interrupt. The functionality is illustrated in Figure. During the period of Ta, only one data sample is made available and, during the rest of the period, the device is maintained in STOP state to reduce power consumption. The microcontroller which receives the data on the Interrupt, is also expected to be processing the data for a short time as shown clearly in the Figure 7 to ensure the overall low-power consumption of the data acquisition and processing system. Figure 7. Standby Mode 1 I DD MCU MCU MCU V, I, T V, I, T ADC t Ta sec. Start SBM1 Channel DATA Register Ta Tconv DATA – A0 sec. DATA – A1 Tconv Ta sec. DATA – A2 Tconv DATA – A3 INT TINT www.ams.com/AS8510 Revision 3.5 20 - 46 AS8510 Datasheet - D e t a i l e d D e s c r i p t i o n 7.4.4 Standby Mode2 (SBM2) Standby Mode 2 is an extension of the Standby Mode1 to achieve even a lower power in the data acquisition system by providing interrupt to the microcontroller only when the data sample exceeds the set current threshold. The Standby Mode can be entered only through the STOP state. Transition to SBM2 mode occurs when the “START BIT” D0 of Mode Control register MOD_CTL_REG in Table 33 is set to “1” and Mode Control Bits D7,D6 to “1,1” through SPI. In this mode the date rate is programmable with the time of Ta in the Ta control registers B, C. The data sample is made available and an interrupt signal is generated on INT pin only when the input signal exceeds the threshold set in Current Threshold Registers D,E. It should be noted here that the data is stable for Ta secs. The functionality is illustrated in Figure 8. Figure 8. Standby Mode 2 I DD MCU |I| > I Threshold I I ADC Ta sec. Start SBM2 Channel DATA Register DATA – A0 Tconv Ta sec. Tconv DATA – A1 Ta sec. DATA – A2 t Tconv DATA – A3 INT TINT 7.5 Reference-Voltage Band gap-reference voltage is used for the ADC as a reference and for the generation of the current for external temperature measurement. 7.6 Oscillators A High-speed oscillator (HS) generates the oversampling clock. For internal state machine and Interrupt generation, a low-speed Oscillator (LS) is also available. 7.7 Power-On Reset The AS8510 has PORs, APOR and DPOR on analog and digital power supplies respectively. On PORs of both supplies, initialization sequence happens and the system status is shown in state diagram (see Figure 4). As shown in the state diagram, the system is in RESET state until DPOR output goes to logic HIGH and subsequently until APOR output goes to logic HIGH. Once analog power supply is available, the system goes into OTP_INT state and loads the default values into the control and data registers and goes into STOP state. If analog POR, APOR goes low at any time, the system goes into RESET state. In the STOP state, the AS8510 can be programmed and by giving start command it starts working following the state machine. www.ams.com/AS8510 Revision 3.5 21 - 46 AS8510 Datasheet - D e t a i l e d D e s c r i p t i o n 7.8 4-Wire Serial Port Interface The SPI interface is used as interface between the AS8510 and an external micro-controller to configure the device and access the status information. The micro-controller begins communication with the SPI which is configured as a slave. The SPI protocol is simple and the length of each frame is an integer multiple of bytes except when a transmission is started. Each frame has 1 command bit, 7 address/configuration bits, and one or more data bytes. The edge of CS and the level of SCLK during the start of a SPI transaction, determine the edge on which the data is transferred from the SPI and the edge on which the data is sampled by the slave. Table 29 describes the setting of the transfer and sampling edges of SCLK. Figure 9 shows the falling edge and rising edge for data transfer and data sampling respectively, when SCLK is HIGH on the falling edge of CS. Table 29. CS and SCLK CS SCLK Description FALL LOW Serial data transferred on rising edge of SPI clock. Sampled at falling edge of SPI clock. FALL HIGH Serial data transferred on falling edge of SPI clock. Sampled at rising edge of SPI clock. ANY ANY Serial data transfer edge is unchanged. Figure 9. Protocol for Serial Data Write with Length = 1 CS SCLK 0 SDI A6 A5 A4 A3 A2 A1 A0 D7 D6 D5 D4 D3 D2 D1 D0 SDO Transfer edge 7.8.1 Data D7 – D0 is moved to Address A4..A0 here Sampling edge SPI Frame A frame is formed by a first byte for command and address/configuration and a following bit stream that can be formed by an integer number of bytes. Command is coded on the 1 first bit, while address is given on LSB 7 bits (see Table 30). Table 30. Command Bits Command Bits Register Address or Transmission Configuration C0 A6 A5 A4 A3 A2 A1 C0 Command <A6:A0> Description 0 WRITE ADDRESS Writes data byte on the given starting address. 1 READ ADDRESS Read data byte from the given starting address. A0 Table 31. Command Bits If the command is read or write, one or more bytes follow. When the micro-controller sends more bytes (keeping CS LOW and SCLK toggling), the SPI interface increments the address of the previous data byte and writes/reads data to/from consecutive addresses. www.ams.com/AS8510 Revision 3.5 22 - 46 AS8510 Datasheet - D e t a i l e d D e s c r i p t i o n 7.8.2 Write Command For write command, C0=0. After the command code C0 is transferred, the address of register to be written is provided from MSB to LSB. Subsequently one or more data bytes can be transferred from MSB to LSB. For each data byte following the first one, used address is the incremented value of the previously written address. Each bit of the frame has to be driven by the SPI master on the SPI clock transfer edge. The SPI slave samples it on the next clock edge. These edges are determined by the level of SCLK as shown in Table 29. Figure 10 and Figure 11 are examples of write command without and with address self-increment. Figure 10. Protocol for Serial Data Write with Length = 1 CS SCLK 0 SDI A6 A5 A4 A3 A2 A1 A0 D7 D6 D5 D4 D3 D2 D1 D0 SDO Data D7 – D0 is moved to Address A4..A0 here Figure 11. Protocol for Serial Data Write with Length = 4 CS SCLK SDI 0 AA A A A A A DD D D D D D D DD D D D D D D DD D D D D D D DD D D D D D D DD D D D D D D 65 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 SDO Data D7-D0 is moved to Address A4-A0 here www.ams.com/AS8510 Data D7-D0 is moved to Address A4-A0 +1 here Revision 3.5 Data D7-D0 is moved to Address A4-A0 +2 here Data D7-D0 is moved to Address A4-A0 +3 here Data D7-D0 is moved to Address A4-A0 +4 here 23 - 46 AS8510 Datasheet - D e t a i l e d D e s c r i p t i o n 7.8.3 Read Command For Read command C0=1. After the command code C0, the address of register to be read is provided from MSB to LSB. Then one or more data bytes can be transferred from the SPI slave to the master, always from MSB to LSB. To transfer more bytes from consecutive addresses, SPI master keeps CS signal LOW and SPI clock active as long as it desires to read data from the slave. Each bit of the command and address of the frame is to be driven by the SPI master on the SPI clock transfer edge where SPI slave samples it on the next SPI clock edge. Each bit of the data section of the frame is driven by the SPI slave on the SPI clock transfer edge and SPI master samples it on the next SPI clock edge. These edges are determined as per Table 29 and examples of read command without and with address self-increment. Figure 12. Protocol for Serial Data Read with Length = 1 CS SCLK 1 SDI A6 A5 A4 A3 SDO A2 A1 A0 D7 D6 D5 D4 D3 D2 D1 D0 Data D7 – D0 at Address A4..A0 is read here Figure 13. Protocol for Serial Data Read with Length = 4 CS SCLK SDI 1 A A A A A A A 6 5 4 3 2 1 0 SDO D D D D D D D D D D D D D D D D D D D D D D D D D D D DD D D D D D D D D D D D 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 43 2 1 0 7 6 5 4 3 2 1 0 Data D7-D0 at Data D7-D0 at Data D7-D0 at Data D7-D0 at Data D7-D0 at Address A4-A0 Address A4-A0 +1 Address A4-A0 +2 Address A4-A0 +3 Address A4-A0 +4 is read here is read here is read here is read here is read here www.ams.com/AS8510 Revision 3.5 24 - 46 AS8510 Datasheet - D e t a i l e d D e s c r i p t i o n 7.8.4 Timing In the following timing waveforms and parameters are exposed. Figure 14. Write Timing for Writing CS ... tCPS t CPHD SCLK tSCLKH tSCLKL tCSH CLK polarity ... tDIS SDI tDIH DATAI ... DATAI DATAI ... SDO Figure 15. Read Timing for Reading CS tSCLKH tSCLKL SCLK SDI DATAI DATAI tDOD SDO www.ams.com/AS8510 DATAO (D7 ) Revision 3.5 t DOHZ DATAO (D0 ) 25 - 46 AS8510 Datasheet - D e t a i l e d D e s c r i p t i o n 7.8.5 SPI Interface Timing Table 32. SPI Interface Timing Symbol Parameter Conditions Min Typ Max Units 1 Mbps General BRSPI Bit rate TSCLKH Clock high time 400 ns TSCLKL Clock low time 400 ns tDIS Data in setup time 20 ns tDIH Data in hold time 20 ns TCSH CS hold time 20 ns Write timing Read timing tDOD Data out delay tDOHZ Data out to high impedance delay Time for the SPI to release the SDO bus 80 ns 80 ns Timing parameters when entering 4-Wire SPI mode (for determination of CLK polarity) tCPS Clock setup time (CLK polarity) Setup time of SCLK with respect to CS falling edge 20 ns tCPHD Clock hold time (CLK polarity) Hold time of SCLK with respect to CS falling edge 20 ns www.ams.com/AS8510 Revision 3.5 26 - 46 AS8510 Datasheet - D e t a i l e d D e s c r i p t i o n 7.9 Control Register This section describes the control registers used in AS8510. Registers can be broadly classified into the following categories. Data access registers Status Registers Digital signal path control registers Digital Control registers Analog Control Registers Table 33. Control Registers Addr in HEX Register Name POR Value R/W 8-bit Control / Status Data Data Access Registers 00 DREG_I1 (ADC Data Register for Current) 0000_0000 R D[7:0] Denotes the Current ADC MSB Byte (ADC_I[15:8]) 01 DREG_I2 (ADC Data Register for Current) 0000_0000 R D[7:0] Denotes the Current ADC LSB Byte (ADC_I[7:0]) 02 DREG_V1 (ADC Data Register for Voltage) 0000_0000 R D[7:0] Denotes the Voltage ADC MSB Byte (ADC_V[15:8]) 03 DREG_V2 (ADC Data Register for Voltage) 0000_0000 R D[7:0] Denotes the Voltage ADC LSB Byte (ADC_V[7:0]) D[7] NOM1/NOM2 Data Ready D[6] NOM2 Threshold Crossover D[5] SBM1 Data Ready D[4] SBM2 Threshold Crossover D[3] APOR status D[2] Data from current channel updated D[1] Data from voltage channel updated D[0] Reserved Status Registers 04 www.ams.com/AS8510 STATUS_REG 0000_0000 R Revision 3.5 27 - 46 AS8510 Datasheet - D e t a i l e d D e s c r i p t i o n Table 33. Control Registers Addr in HEX Register Name POR Value R/W 8-bit Control / Status Data Digital Signal Path Control Registers for Current Channel D[7] This bit selects decimation rate is used for current channel. Default is 0 (Down Sampling Rate is 64) 0 Down Sampling Rate is 64 1 Down Sampling Rate is 128 These two bits select division ratio of oversampling frequency clock MOD_CLK to be used as chopper clock, CHOP_CLK. Default is “10” (divide by 512) D[6:5] 00 Chopper Clock Always High 01 Divide by 256 10 Divide by 512 11 Divide by 1024 These four bits select the decimation ratio of second CIC stage. Default is “0010” (equal to 4) 05 DEC_REG_R1_I 0100_ 0101 R/W D[4:1] 0000 1 0001 2 0010 4 0011 8 0100 16 0101 32 0110 64 0111 128 1000 256 1001 512 1010 1024 1011 2048 1100 4096 1101 8192 1110 16384 1111 32768 CIC1 Saturation Interrupt Mask Control. Default is 1 D[0] www.ams.com/AS8510 Revision 3.5 0 Unmask 1 Mask 28 - 46 AS8510 Datasheet - D e t a i l e d D e s c r i p t i o n Table 33. Control Registers Addr in HEX Register Name POR Value R/W 8-bit Control / Status Data D[7] I-Channel Enable, Default 1=enable D[6] V-Channel Enable, Default 1=enable Interrupt polarity D[5] 0 Active high 1 Active low . Interrupt Mask Control for Current Channel Data Ready Interrupt on INT pin (Default is 0) D[4] 06 DEC_REG_R2_I 1100_0101 0 Unmasked 1 Masked These two bits select the source of output 16-bit data in Normal mode from Current channel. Default is 01 R/W 00 D[3:2] FIR / MA Output 01 CIC2 Output 10 Dechop/Demod Output 11 CIC1 Output These two bits select the source of output 16-bit data in SBM mode from Current channel. Default is 01 D[1:0] www.ams.com/AS8510 Revision 3.5 00 FIR / MA Output 01 CIC2 Output 10 Dechop/Demod Output 11 CIC1 Output 29 - 46 AS8510 Datasheet - D e t a i l e d D e s c r i p t i o n Table 33. Control Registers Addr in HEX Register Name POR Value R/W 8-bit Control / Status Data This bit selects FIR / MA Filter in Current channel. Default is 0 (FIR) D[7] 0 FIR 1 MA Filter These bits select the number of data samples for averaging in MA filter in Current channel. Default is 0000 (bypass) D[6:3] 07 FIR CTL_REG_I 0000_0100 R/W 0000 bypass 0001 1 0011 3 0111 7 1111 15 These two bits select the Measurement Path architecture in both Current and Voltage channels. Default is 10 (Dechopper after CIC) D[2:1] D[0] www.ams.com/AS8510 Revision 3.5 00 Demodulator after CIC1 01 Demodulator before CIC1 10 Dechopper after CIC1 (preferred and suggested) 11 Demodulator before CIC1 with settled sample Reserved. Default 0. Do not change 30 - 46 AS8510 Datasheet - D e t a i l e d D e s c r i p t i o n Table 33. Control Registers Addr in HEX Register Name POR Value R/W 8-bit Control / Status Data Digital Control Registers Oversampling frequency clock selection. Default is 00 (high speed (HS) internal Clock) D[7:6] 00 Internal HS Clock with No Clock Output 01 Internal HS Clock with Clock Output 10 External Clock These two bits select the division ratio for HS clock/ external clock. Default is 10 (division by 4) D[5:4] 08 CLK_REG (Clock Control Register) 0010_0000 R/W 00 No division 01 Divide by 2 10 Divide by 4 11 Divide by 8 These two bits select the division ratio of HS clock, by which it should be divided before providing it on CLK pin. Default is 00 (No Division) D[3:2] 00 No Division 01 Divide by 2 10 Divide by 4 11 Divide by 8 This bit selects the division ratio of LS clock D[1] 09 RESET_REG (Reset Control Register) www.ams.com/AS8510 1100_0000 R/W 0 LS _CLK undivided (Low Speed clock) 1 LS _CLK divide by 2 D[0] Reserved D[7] Entire device can be soft reset by writing “0” into this register bit. This bit will take a default 1 value on coming out of Reset D[6] Measurement Path can be soft reset by writing “0” into this register bit. This bit will take a default 1 value after Measurement Path is reset. D[5:0] Reserved Revision 3.5 31 - 46 AS8510 Datasheet - D e t a i l e d D e s c r i p t i o n Table 33. Control Registers Addr in HEX Register Name POR Value R/W 8-bit Control / Status Data These two bits select the operating mode of the Device. Default is 00 (Normal Mode 1) D[7:6] 00 Normal Mode 1 01 Normal Mode 2 10 Standby Mode 1 11 Standby Mode 2 These three bits select the number of cycles to be ignored before comparison with the set threshold in Standy Mode. Default is 000 (3 cycles of data) D[5:3] 0A MOD_CTL_REG (Mode Control Registers) 0000_0000 R/W D[2] 000 3 cycles of data 001 4 cycles of data 010 5 cycles of data 011 6cycles of data 100 7 cycles of data 101 8 cycles of data 110 9 cycles of data 111 10 cycles of data This bit controls the CHOP_CLK availability on CHOP_CLK pin. Default is 0 0 Disabled 1 Enabled Enabling the MEN pin to indicate transition from Standby to Normal Mode. D[1] 0 Disabled 1 Enabled This bit is used to take the device from STOP state to any of the Modes based on D[7:6] selection of this register. D[0] 0 Retain in STOP state 1 Enables transition to Normal or Standby Modes. Unit of Ta in SBM1/SBM2. Default is 1 0B MOD_Ta_REG1 (Ta Control Register) D[7] 1000_0000 0 Unit is in milliseconds 1 Unit is in seconds D[6:0] MSB value of Ta 0C MOD_Ta_REG2 (Ta Control Register) 0000_0000 R/W D[7:0] Unit of Ta in SBM1/SBM2 LSB value of Ta 0D MOD_ITH_REG1 (Current Threshold Register) 0000_0000 R/W D[7:0] MSB bits of 16 bits SBM2 threshold register 0E MOD_ITH_REG2 (Current Threshold Register) 0000_0000 R/W D[7:0] LSB bits of 16 bits SBM2 threshold register www.ams.com/AS8510 Revision 3.5 32 - 46 AS8510 Datasheet - D e t a i l e d D e s c r i p t i o n Table 33. Control Registers Addr in HEX Register Name POR Value R/W 0F MOD_TMC_REG1 (TMC Control Registers) 0000_0000 R/W D[7:0] MSB value of number of data samples to be dropped from ADC before sending Interrupt in NOM2 10 MOD_TMC_REG2 (TMC Control Register) 0000_0000 R/W D[7:0] LSB value of number of data samples to be dropped from ADC before sending Interrupt in NOM2 11 NOM_ITH_REG1 0000_0000 R/W D[7:0] Eight MSB bits of NOM2 current threshold register 12 NOM_ITH_REG2 0000_0000 R/W D[7:0] Eight LSB bits of NOM2 current threshold register 8-bit Control / Status Data Analog Control Registers Setting of Gain G of Current Channel PGA. Default is 01 (G = 25) D[7:6] 13 PGA_CTL_REG (PGA Control Registers) 0101_0000 R/W 00 5 01 25 10 40 11 100 Setting of Gain G in Voltage channel. Default is 01 (G = 25) D[5:4] 00 5 01 25 10 40 11 100 D[3:0] D[7] D[6] 14 PD_CTL_REG_1 (Power Down Control Register) 1100_1111 R/W 0 Disable Chopper clock to Current channel 1 Enable Chopper clock to Current channel 0 Disable Chopper clock to Voltage channel 1 Enable Chopper clock to Voltage channel D[5] Reserved D[4] Reserved D[3] D[2] D[1] D[0] www.ams.com/AS8510 Reserved Revision 3.5 0 Disable Current channel PGA 1 Enable Current channel PGA 0 Disable Current channel ΣΔ Modulator 1 Enable Current channel ΣΔ Modulator 0 Disable Voltage channel PGA 1 Enable Voltage channel PGA 0 Disable Voltage channel ΣΔ Modulator 1 Enable Voltage channel ΣΔ Modulator 33 - 46 AS8510 Datasheet - D e t a i l e d D e s c r i p t i o n Table 33. Control Registers Addr in HEX Register Name POR Value R/W 8-bit Control / Status Data D[7] D[6] D[5] D[4] 15 PD_CTL_REG_2 (Power Down Control Register) 1111_0011 R/W D[3] D[2] D[1] D[0] D[7] D[6] D[5] 16 PD_CTL_REG_3 (Power Down Control Register) 1111_1000 Disable CIC1 of both channels 1 Enable CIC1 of both channels 0 Disable CIC2 of both channels 1 Enable CIC2 of both channels 0 Disable Dechopper in both channels 1 Enable Dechopper in both channels 0 Disable FIR in both channels 1 Enable FIR in both channels 0 Do not bypass PGA in Current Channel Default 0 1 Bypass PGA in Current Channel 0 Do not bypass PGA in Voltage Channel Default 0 1 Bypass PGA in Voltage Channel 0 Disable Current Channel Chopper 1 Enable Current Channel Chopper 0 Disable Voltage Channel Chopper 1 Enable Voltage Channel Chopper 0 Disable Common Mode Reference 1 Enable Common Mode Reference 0 Disable Internal Current Source 1 Enable Internal Current Source 0 Disable Internal temperature sensor 1 Enable Internal temperature sensor D[4] Reserved. (Default 1) Do not change D[3] Reserved. (Default 1) Do not change D[2] www.ams.com/AS8510 0 0 Data Output in binary numbering system 1 Data Output in 2’s complement numbering system D[1] Reserved. (Default 0) Do not change D[0] Reserved Revision 3.5 34 - 46 AS8510 Datasheet - D e t a i l e d D e s c r i p t i o n Table 33. Control Registers Addr in HEX Register Name POR Value R/W 8-bit Control / Status Data These bits specify the selection of voltage/temperature in Voltage Channel Default is 00 (Voltage Channel) D[7:6] 00 Voltage Channel 01 External Temperature Channel ETR 10 External Temperature Channel ETS 11 Internal Temperature Channel D[5] Reserved. (Default 0) Do not change Internal current source switch enable. Default is 0 17 ACH_CTL_REG (Analog Channel Selection Register) 0000_0000 R/W D[4] Note: D4 bit is used for Enabling current source to the channel selected by bits D[7,6] of this register. 0 Disabled 1 Enabled Enable/disable Internal current source to RSHH pin of Current channel D[3] 0 Disabled 1 Enabled Enable/disable current source switch to RSHL pin of Current channel D[2] 0 Disabled 1 Enabled D[1:0] Reserved These three bits specify the selection of magnitude of current from the Internal current source. Default is 00000 (0µA). 18 ISC_CTL_REG (Current Source Setting Register) 0000_0000 R/W D[7:3] 00000 0µA 00001 8.5µA 00010 17µA 00100 34.5µA 01000 68µA 10000 135µA 11111 270µA 1 Reserved (default = 1) Do not change D[2:0] 19 44 www.ams.com/AS8510 OTP_EN_REG STATUS_REG_2 0000_0000 0000_0000 R/W R D[7] Reserved D[6:0] Reserved D[7] Status indicating data saturation in Current channel D[6] Status indicating data saturation in Voltage channel D[5:0] Reserved Revision 3.5 35 - 46 AS8510 Datasheet - D e t a i l e d D e s c r i p t i o n Table 33. Control Registers Addr in HEX Register Name POR Value R/W 8-bit Control / Status Data Digital Signal path control registers for Voltage Channel D[7] Selection of Decimation ratio for Voltage/Temperature channel. Default is 0 (Down Sampling Rate is 64) 0 Down Sampling Rate is 64 1 Down Sampling Rate is 128 Division of oversampling clock, which is used as Chopper Clock. Default is 10 (divide by 512) D[6:5] 00 Chopper Clock Always High 01 Divide by 256 10 Divide by 512 11 Divide by 1024 Decimation ratio of CIC2. Default is 0010 (4) 45 DEC_REG_R1_V 0100_ 0101 R/W D[4:1] 0000 1 0001 2 0010 4 0011 8 0100 16 0101 32 0110 64 0111 128 1000 256 1001 512 1010 1024 1011 2048 1100 4096 1101 8192 1110 16384 1111 32768 CIC1 Saturation Interrupt Mask Control. Default is 1 D[0] www.ams.com/AS8510 Revision 3.5 0 Unmasked 1 Masked 36 - 46 AS8510 Datasheet - D e t a i l e d D e s c r i p t i o n Table 33. Control Registers Addr in HEX Register Name POR Value R/W 8-bit Control / Status Data D[7:5] Reserved Interrupt Mask Control for Voltage channel data Ready Interrupt on INT pin (Default is 0) D[4] 46 DEC_REG_R2_V 0000_0100 0 Unmasked 1 Masked These two bits select the source of output 16-bit data in Normal mode from Voltage channel. Default is 01 R/W D[3:2] 00 FIR / MA Output 01 CIC2 Output 10 Dechop/Demod Output 11 CIC Output D[1:0] Reserved This bit selects FIR / MA Filter in Voltage channel. Default is 0 (FIR) D[7] 47 FIR CTL_REG_V 0000_0000 0 FIR 1 MA Filter These bits select the number of data samples for averaging in MA filter in Voltage channel. Default is 0000 (bypass) R/W 0000 D[6:3] bypass 0001 1 0011 3 0111 7 1111 D[2:0] 15 Reserved Note: All the registers from address 0x19 to 0x2C are read-only. 7.9.1 Standby Mode - Power Consumption In Standby Mode 1 there is a timer based accurate measurement every Ta seconds. The device itself stays in idle-mode as long as it does not get a different command from the SPI interface. Internal oscillator frequency is typically foscint=262 kHz to reduce power consumption as long as the timer runs. After every time out of Ta secs, it performs accurate measurement of current, voltage/ temperature. Data ready is signaled to microcontroller through an interrupt signal on INT and goes into STOP state. In the SBM the following equations hold: Tsbm1 = Ta= 10s (default value is 10secs); the power consumption is valid for this setting. This is the period of the repetition rate in SBM 1 and SBM2. Tsett ≈ 2ms (depending on external capacitors). This is the time required by the analog part to settle when the new measuring period is started. Any measurements performed during Tsett produce invalid results. T1 = 3ms (by default setting, every third measurement is sent to microcontroller in the SBM mode 1) is the time needed to perform the first measurement. Tmeas =Tsett +T1 is the total active time needed to get a valid result. DRSBM = Tmeas/Tsbm ≈ 5ms/10s. This is the ratio of repetition time versus the active time (Device in NOM mode). Power consumption = (DRSBM*NOM mode power consumption) + ((10s-5ms)/10s)*Stop mode power consumption) www.ams.com/AS8510 Revision 3.5 37 - 46 AS8510 Datasheet - D e t a i l e d D e s c r i p t i o n 7.9.2 Initialization Sequence at Power ON Figure 16. AS8510 Device Initialization Sequence at Power ON VPORHID/VPORHIA DVDD/AVDD POR_N Start ADC 1.5mS TADC INT 500µS CHOP_CLK Configure Device D1 Channel Data Register D2 D3 D4 D1 0x0000 D2 D3 D4 D1 DATA1 TDATA_STATUS_RD TDATA_VALID D2 D3 D4 DATA2 TDATA_INVALID Device initialization starts if the DVDD and AVDD supplies are switched ON and DVDD > VPORHID. The duration period of Initialization is 500μsec and during this period, INT pin toggles at the rate of internal low power oscillator. Toggling on INT during the period of initialization should be ignored in the system. Device configuration and activation should be carried out only after the initialization period. On ADC start, device enters into analog stabilization state and takes 1.5msec for oscillator and Reference to settle. After this 1.5msec period, the first interrupt will occur after a time period of TADC. TDATA_STATUS_RD is the time period during which the micro-controller should complete reading of data and status from the device. If reading is carried out beyond this time period, then, ADC performance will degrade for next sample generation. Status register gets cleared automatically only when micro-controller reads this register. Data in the channel registers is changed after TDATA_VALID duration. Ensure that data channel registers and status registers are not read during the TDATA_INVALID duration. Example: Configuration registers are set as follows: CLK_REG = 8’b0010_0000 DEC_REG_R1_I = 0100_0101 DEC_REG_R2_I = 1100_0101 FIR_CTL_REG_I = 0000_0100 ADC is configured to a data rate of 1KHz, CHOP_CLK to 2KHz, and Modulator clock to 1MHz, Decimation ratio of CIC1 = 64, and Decimation ratio of CIC2 = 4. With these settings the various time periods as shown in the Figure 16 are as follows: TDATA_STATUS_RD = 100 μsec (TDATA_STATUS_RD = (1/mod_clk) * R1 * [((mod_clk/(2*chop_clk))*(1/R1)) - 2.5) TDATA_INVALID = 8 μsec TADC = 1msec TDATA_VALID = TADC - TDATA_INVALID = 1msec - 8 μsec CHOP_CLK and POR_N are internal signals of the device. www.ams.com/AS8510 Revision 3.5 38 - 46 AS8510 Datasheet - D e t a i l e d D e s c r i p t i o n Table 34 provides valid combinations of Modulator clock, Chopper clock and Decimation R1 and the corresponding values of TDATA_STATUS_RD and TADC. Table 34. Valid Combinations of Modulator Clock, Chopper Clock and Decimation Ratio R1 Modulator Clock Chopper Frequency CHOP_CLK Decimation Ratio R1 TDATA_STATUS_RD TADC R2/(2*CHOP_CLK) for R2=4 1.024MHz 2KHz 64 1usec * 64 * [4 - 2.5] = 96usec 1mSec 2.048MHz 2KHz 64 2.048MHz 2KHz 128 2.048MHz 4KHz 64 7.9.3 0.5usec * 64 * [8 - 2.5] = 176usec 1mSec 0.5usec * 128 * [4 - 2.5] = 96usec 1mSec 0.5usec * 64 * [4 - 2.5] = 48usec 0.5mSec Soft-reset of Device Using Bit D[7] of Reset Register 0x09 It is possible to soft-reset the device by writing “0” into D[7] bit of Reset Register at 0x09. On applying soft-reset, the device enters into initialization state and D[6] bit changes back to “1”. The duration period of Initialization is 500μsec, and, during this period, INT pin toggles at the rate of internal low power oscillator. Toggling on INT during the period of initialization should be ignored in the system. Device configuration and activation should be carried out only after the initialization period. See Figure 17 for the timing details of the sequence of device initialization on soft-reset. Figure 17. AS8510 Device Initialization Sequence at Soft-reset Start ADC 1.5mS INT D4 D1 D2 D3 D4 500µS D1 Soft Reset Using D7 D1 Re-Configure Device D2 D 3 D4 D1 D2 D3 D4 D1 D2 D3 D4 CHOP_CLK Channel Data DATA-N Register TDATA_STATUS_RD TDATA_VALID 7.9.4 DATA-N+1 0x0000 DATA1 TDATA_STATUS_RD TDATA_INVALID TDATA_VALID DATA2 TDATA_INVALID Soft-reset of the Measurement Path Using Bit D[7] of Reset Register 0x09 Measurement path also can be reset by using D[6] bit of Reset Register at 0x09. On applying soft-reset only signal measurement path registers will be reset. For applying this reset, device should be in STOP state. If the device is working with external clock, at the time of soft-reset the clock needs to be disabled. www.ams.com/AS8510 Revision 3.5 39 - 46 AS8510 Datasheet - D e t a i l e d D e s c r i p t i o n 7.9.5 Reconfiguring Gain Setting of PGA Only PGA gain settings can be changed dynamically while ADC conversions are in progress. When PGA gain settings are changed, the first sample from the ADC is invalid. Ignore the first interrupt after the gain re-configuration. Valid data starts from the second interrupt onwards. Figure 18. AS8510 - Re-configuration of Gain Setting of PGA Gain Re-Configuration can be carried out in this slot, skip next interrupt and Channel Data. Read Channel data in this slot VALID DATA TDATA_STATUS_RD INT D4 D1 D2 D3 D4 D1 D2 D3 D4 D1 D2 D3 D4 D1 D2 D3 D4 CHOP_CLK Channel Data Register DATA-N TDATA_STATUS_RD TDATA_VALID 7.9.6 DATA-N+1 DATA1 TDATA_STATUS_RD TDATA_INVALID TDATA_VALID DATA2 TDATA_INVALID Configuring the Device During Normal Mode Following registers can be programmed dynamically when the device is in operational mode (Normal mode). ACH_CTL_REG address is 0x17 for channel selection on the voltage measurement path PGA_CTL_REG address is 0x13 for gain setting PD_CTL_REG2 address is 0x15 for PGA Bypass ISC_CTL_REG address is 0x18 for current source programmability During the operation (Normal mode) of the device, if any of the registers need to be programmed or changed other than the above mentioned registers, then it is required to STOP the device by writing into MOD_CTL_REG “STOP” bit and configure the device as per the requirements and start the device. www.ams.com/AS8510 Revision 3.5 40 - 46 AS8510 Datasheet - D e t a i l e d D e s c r i p t i o n 7.10 Low Side Current Measurement Application Figure 19. Application Diagram RSHH INT RSHL CLK REF SDI VCM MEN 100nF 100nF 3.3V AVDD 1µF +12V 481 R R AS8510 20 pin (SSOP20) CHOP_CLK AVSS DVDD ETR DVSS ETS SDO 3.3V 1µF SCLK VBAT_IN CS VBAT_GND 100 µohm + 12V Battery - www.ams.com/AS8510 Load µC Note: On ETR connect constant resistor (temp co = 0) On ETS connect Temperature sensor (use sensor resistor more than 10K) Revision 3.5 41 - 46 AS8510 Datasheet - P a c k a g e D r a w i n g s a n d M a r k i n g s 8 Package Drawings and Markings The product is available in a 20-pin SSOP package. Figure 20. Drawings and Dimensions Symbol A A1 A2 b c D E E1 e L L1 L2 R θ N YYWWIXX AS8510 www.ams.com/AS8510 Revision 3.5 Min 0.05 1.65 0.22 0.09 6.90 7.40 5.00 0.55 0.09 0º Nom 1.75 7.20 7.80 5.30 0.65 BSC 0.75 1.25 REF 0.25 BSC 4º 20 Max 2.00 1.85 0.38 0.25 7.50 8.20 5.60 0.95 8º 42 - 46 AS8510 Datasheet - P a c k a g e D r a w i n g s a n d M a r k i n g s Notes: 1. Dimensions & tolerancing conform to ASME Y14.5M-1994. 2. All dimensions are in millimeters. Angles are in degrees. Marking: YYWWIXX. YY WW I XX Last two digits of the current year Manufacturing week Assembly plant identifier Assembly traceability code 8.1 Recommended PCB Footprint Figure 21. PCB Footprint Recommended Footprint Data Symbol mm A 9.02 B 6.16 C 0.46 D 0.65 E 6.31 www.ams.com/AS8510 Revision 3.5 43 - 46 AS8510 Datasheet - R e v i s i o n H i s t o r y Revision History Revision Date Owner Description 1.1 Jun 22, 2009 mbr Initial version Dec 02, 2009 ss2, rad 1.2 Dec 08, 2009 ss2 Updated the datasheet according to 1.8 specification Following modifications carried out in Table 27: 1) Deleted Max value for parameter ‘Temperature upper limit’ 2) Added Footnote 2 3) Added new parameter ‘Temperature Sensor Output (without gain calibration) Updated Table 15 with PGA information 1.3 Feb 19, 2010 mbr Updated Voltage Measurement Updated VREFand VIN values in Table 17 and VREF in Table 18 Inserted new Table 28 - System Measurement Error Budget Changed the pin name AGND to VCM Current source added in the block diagram 2.0 June 01, 2010 mbr Added application diagram Updated Electrical Characteristics on page 7 Updated Detailed System and Block Specifications on page 9 Updated Standby Mode - Power Consumption on page 37 3.0 Oct 29, 2010 ss2 Updates carried out across the datasheet 3.1 Nov 02, 2010 ss2 Updated Ref Voltage Offset in Table 18 3.2 Nov 14, 2010 ss2 Added sections 7.9.2, 7.9.3, 7.9.5 Nov 26, 2010 vel Formatted figures 17, 18 in portrait mode. Index modified from page 39 Dec 03, 2010 ss2 Added Configuring the Device During Normal Mode on page 40 3.3 3.4 3.5 Mar 01, 2011 mbr /ss2 Aug 05, 2011 mbr,ss2,vel Dec 31, 2012 sju Updated General Description, Key Features, Applications, Pin Descriptions, Current Measurement Ranges, Differential Input Amplifier for Current Channel, Differential Input Amplifier for Voltage Channel, Sigma Delta Analog to Digital Converter, Bandgap Reference Voltage, System Measurement Error Budget for Gains 5 and 25, Package Drawings and Markings. Deleted Voltage Measurement. Updated Table 14, Figure 4, Table 19, Table 18, Section 7.9.6, Figure 19. Added Section 7.9.4 Updated ordering table. Note: Typos may not be explicitly mentioned under revision history. www.ams.com/AS8510 Revision 3.5 44 - 46 AS8510 Datasheet - O r d e r i n g I n f o r m a t i o n 9 Ordering Information The devices are available as the standard products shown in Table 35. Table 35. Ordering Information Ordering Code Description Delivery Form Package AS8510-ASSP Data Acquisition Device for Battery Sensors Tape and Reel (2000 pcs) 20-pin SSOP AS8510-ASSM Data Acquisition Device for Battery Sensors Tape and Reel (500 pcs) 20-pin SSOP Note: All products are RoHS compliant and ams green. Buy our products or get free samples online at www.ams.com/ICdirect Technical Support is available at www.ams.com/Technical-Support For further information and requests, email us at [email protected] (or) find your local distributor at www.ams.com/distributor www.ams.com/AS8510 Revision 3.5 45 - 46 AS8510 Datasheet - C o p y r i g h t s Copyrights Copyright © 1997-2012, ams AG, Tobelbaderstrasse 30, 8141 Unterpremstaetten, Austria-Europe. Trademarks Registered ®. All rights reserved. The material herein may not be reproduced, adapted, merged, translated, stored, or used without the prior written consent of the copyright owner. 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